Layering of low thermal conductive material on metal tray

ABSTRACT

An ice maker having a housing defining an interior volume, with an ice tray rotatably coupled with the housing and horizontally suspended across the interior volume thereof. The ice tray has ice wells, defined along the bottom by a bottom surface and the sides by an interior surface of at least one containment wall, wherein the containment wall has an upper portion, including a top surface of the containment wall and the interior surface adjacent the top surface. The upper portion of the containment wall has an insulating layer applied thereto. A tray for use in the ice maker and method of manufacturing the tray are also provided.

RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 15/095,995 entitled “LAYERING OF LOW THERMAL CONDUCTIVEMATERIAL ON METAL TRAY” filed on Apr. 11, 2016. U.S. patent applicationSer. No. 15/095,995 is a division of U.S. patent application Ser. No.13/713,206 entitled “Layering of Low Thermal Conductive Material onMetal Tray” filed on Dec. 13, 2012, now U.S. Pat. No. 9,310,115, theentire contents of which is hereby incorporated by reference.

U.S. patent application Ser. No. 13/713,206 is related to, and herebyincorporates by reference the entire disclosures of, the followingapplications for United States Patents: U.S. patent application Ser. No.13/713,283, entitled “Ice Maker with Rocking Cold Plate,” filed on Dec.13, 2012; U.S. patent application Ser. No. 13/713,199, entitled “ClearIce Maker with Warm Air Flow,” filed on Dec. 13, 2012; U.S. patentapplication Ser. No. 13/713,296, entitled “Clear Ice Maker with VariedThermal Conductivity,” filed on Dec. 13, 2012; U.S. patent applicationSer. No. 13/713,244, entitled “Clear Ice Maker,” filed on Dec. 13, 2012;U.S. patent application Ser. No. 13/713,233, entitled “Clear Ice Maker,”filed on Dec. 13, 2012; U.S. patent application Ser. No. 13/713,228,entitled “Twist Harvest Ice Geometry,” filed on Dec. 13, 2012; U.S.patent application Ser. No. 13/713,262, now U.S. Pat. No. 9,303,903,entitled “Cooling System for Ice Maker,” filed on Dec. 13, 20112; U.S.patent application Ser. No. 13/713,218, entitled “Clear Ice Maker andMethod for Forming Clear Ice,” filed on Dec. 13, 2012; U.S. patentapplication Ser. No. 13/713,253, entitled “Clear Ice Maker and Methodfor Forming Clear Ice,” filed on Dec. 13, 2012. The entire contents ofeach of the above applications are hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention generally relates to an ice maker for makingsubstantially clear ice pieces, and methods for the production of clearice pieces. More specifically, the present invention generally relatesto an ice maker and methods which are capable of making substantiallyclear ice without the use of a drain.

BACKGROUND OF THE INVENTION

During the ice making process when water is frozen to form ice cubes,trapped air tends to make the resulting ice cubes cloudy in appearance.The trapped air results in an ice cube which, when used in drinks, canprovide an undesirable taste and appearance which distracts from theenjoyment of a beverage. Clear ice requires processing techniques andstructure which can be costly to include in consumer refrigerators andother appliances. There have been several attempts to manufacture clearice by agitating the ice cube trays during the freezing process to allowentrapped gases in the water to escape.

SUMMARY OF THE INVENTION

One aspect of the present invention includes an ice forming tray formaking clear ice, having an ice well, defined along its bottom by abottom surface and its sides by at least one wall extending upwardlyfrom the bottom surface, wherein the bottom surface and the at least onewall comprise a conductive material. Each of the at least one wallscomprises an interior surface which is facing the ice well, a topsurface which is generally opposite the bottom surface, and an upperportion, comprising the top end and the interior surface adjacentthereto and an insulating layer applied to the upper portion.

Another aspect of the present invention is a method of manufacturing anice forming tray. The method includes the step of providing an iceforming tray with at least one ice well defined along its bottom by abottom surface and its sides by at least one wall extending upwardlyfrom the bottom surface, wherein each of the at least one wallscomprises an interior surface which is facing the ice well, a topsurface which is generally opposite the bottom surface, and an upperportion comprising the top end and the interior surface adjacentthereto. The method also includes the step of applying an insulatinglayer to the upper portion.

Another aspect of the present invention is an ice maker having a housingdefining an interior volume. An ice tray is rotatably coupled with thehousing and horizontally suspended within the interior volume of thehousing, and comprises a conductive tray having ice wells therein. Eachice well is defined along its bottom by a bottom surface and its sidesby at least one wall extending upwardly from the bottom surface. Thebottom surface and the at least one wall comprises a conductivematerial, and wherein each of the at least one walls comprises aninterior surface which is facing the ice well, a top surface which isgenerally opposite the bottom surface, and an upper portion, comprisingthe top end and the interior surface adjacent thereto. An insulatinglayer is applied to the upper portion and a cooling source is thermallycoupled to the bottom of the ice forming tray and configured to freezewater retained within the ice wells.

These and other features, advantages, and objects of the presentinvention will be further understood and appreciated by those skilled inthe art by reference to the following specification, claims, andappended drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIG. 1 is a top perspective view of an appliance having an ice maker ofthe present invention;

FIG. 2 is a front view of an appliance with open doors, having an icemaker of the present invention;

FIG. 3 is a flow chart illustrating one process for producing clear iceaccording to the invention;

FIG. 4 is a top perspective view of a door of an appliance having afirst embodiment of an ice maker according to the present invention;

FIG. 5 is a top view of an ice maker according to the present invention;

FIG. 6 is a cross sectional view of an ice maker according to thepresent invention taken along the line 6-6 in FIG. 5;

FIG. 7A is a cross sectional view of an ice maker according to thepresent invention, taken along the line 7-7 in FIG. 5, with water shownbeing added to an ice tray;

FIG. 7B is a cross sectional view the ice maker of FIG. 7A, with wateradded to the ice tray;

FIGS. 7C-7E are cross sectional views of the ice maker of FIG. 7A,showing the oscillation of the ice maker during a freezing cycle;

FIG. 7F is a cross sectional view of the ice maker of FIG. 7A, aftercompletion of the freezing cycle;

FIG. 8 is a perspective view of an appliance having an ice maker of thepresent invention and having air circulation ports;

FIG. 9 is a top perspective view of an appliance having an ice maker ofthe present invention and having an ambient air circulation system;

FIG. 10 is a top perspective view of an ice maker of the presentinvention installed in an appliance door and having a cold aircirculation system;

FIG. 11 is a top perspective view of an ice maker of the presentinvention, having a cold air circulation system;

FIG. 12A is a bottom perspective view of an ice maker of the presentinvention in the inverted position and with the frame and motors removedfor clarity;

FIG. 12B is a bottom perspective view of the ice maker shown in FIG.12A, in the twisted harvest position and with the frame and motorsremoved for clarity;

FIG. 13 is a circuit diagram for an ice maker of the present invention;

FIG. 14 is a graph of the wave amplitude response to frequency an icemaker of the present invention;

FIG. 15 is a top perspective view of a second embodiment of an ice makeraccording to the present invention;

FIG. 16 is a top perspective view of a disassembled ice maker accordingto the present invention illustrating the coupling between an ice trayand driving motors;

FIG. 17 is an exploded top perspective, cross sectional view of an icemaker according to the present invention;

FIG. 18 is a partial top perspective, cross sectional view of an icemaker according to the present invention;

FIG. 19 is a side elevational view of an ice maker according to thepresent invention;

FIG. 20 is an end view of an ice maker according to the presentinvention;

FIG. 21 is a cross sectional view taken along line 21-21 in FIG. 19;

FIG. 22 is a cross sectional view taken along line 22-22 in FIG. 19;

FIG. 23 is an exploded side cross sectional view of an ice makeraccording to the present embodiment;

FIG. 24 is a top perspective view of a grid for an ice maker of thepresent invention;

FIG. 25 is a top perspective view of an ice forming plate, containmentwall, thermoelectric device and shroud for an ice maker of the presentinvention;

FIG. 26 is a top perspective view of a thermoelectric device for an icemaker of the present invention;

FIG. 27 is a top perspective view of an ice maker with a housing and airduct according to the present invention;

FIG. 28 is a bottom perspective view of the ice maker with a housing andair duct according to the present invention;

FIG. 29 is a top perspective view of an ice maker with an air ductaccording to the present invention;

FIG. 30 is a top perspective cross sectional view of an ice maker withan air duct according to the embodiment shown in FIG. 29;

FIG. 31A is an end view of an ice maker according to the presentinvention in the neutral position with a cold air circulation system,and with the frame and motors removed for clarity;

FIGS. 31B-C are end views of the ice maker shown in FIG. 31A, showingthe oscillating positions of the ice maker in the freezing cycle;

FIG. 31D is an end view of the ice maker shown in FIG. 31A as invertedfor the harvest cycle;

FIGS. 32A and 32B are end views of the ice maker shown in FIG. 31,showing the inversion and rotation of the grid when in the harvestcycle;

FIGS. 33A-33D are top perspective views of an ice maker according to thepresent invention, during harvesting, through its transition from theneutral position (33A), inversion (33B), rotation of the grid (33C), andtwisting of the grid (33D);

FIG. 34 is a top perspective view of another embodiment of an ice makeraccording to the present invention;

FIG. 35A is a top perspective view of an ice tray and cooling elementaccording to the present invention; and

FIG. 35B is a cross sectional view taken along the line 35B-35B in FIG.35A.

DETAILED DESCRIPTION

For purposes of description herein, the terms “upper,” “lower,” “right,”“left,” “rear,” “front,” “vertical,” “horizontal,” and derivativesthereof shall relate to the ice maker assembly 52, 210 as oriented inFIG. 2 unless stated otherwise. However, it is to be understood that theice maker assembly may assume various alternative orientations, exceptwhere expressly specified to the contrary. It is also to be understoodthat the specific devices and processes illustrated in the attacheddrawings, and described in the following specification are simplyexemplary embodiments of the inventive concepts defined in the appendedclaims. Hence, specific dimensions and other physical characteristicsrelating to the embodiments disclosed herein are not to be considered aslimiting, unless the claims expressly state otherwise.

Referring initially to FIGS. 1-2, there is generally shown arefrigerator 50, which includes an ice maker 52 contained within an icemaker housing 54 inside the refrigerator 50. Refrigerator 50 includes apair of doors 56, 58 to the refrigerator compartment 60 and a drawer 62to a freezer compartment (not shown) at the lower end. The refrigerator50 can be differently configured, such as with two doors, the freezer ontop, and the refrigerator on the bottom or a side-by-siderefrigerator/freezer. Further, the ice maker 52 may be housed withinrefrigerator compartment 60 or freezer compartment or within any door ofthe appliance as desired. The ice maker could also be positioned on anoutside surface of the appliance, such as a top surface as well.

The ice maker housing 54 communicates with an ice cube storage container64, which, in turn, communicates with an ice dispenser 66 such that ice98 can be dispensed or otherwise removed from the appliance with thedoor 56 in the closed position. The dispenser 66 is typically useractivated.

In one aspect, the ice maker 52 of the present invention employs variedthermal input to produce clear ice pieces 98 for dispensing. In anotheraspect the ice maker of the present invention employs a rocking motionto produce clear ice pieces 98 for dispensing. In another, the ice maker52 uses materials of construction with varying conductivities to produceclear ice pieces for dispensing. In another aspect, the icemaker 52 ofthe present invention is a twist-harvest ice maker 52. Any one of theabove aspects, or any combination thereof, as described herein may beused to promote the formation of clear ice. Moreover, any aspect of theelements of the present invention described herein may be used withother embodiments of the present invention described, unless clearlyindicated otherwise.

In general, as shown in FIG. 3, the production of clear ice 98 includes,but may not be limited to, the steps of: dispensing water onto an iceforming plate 76, cooling the ice forming plate 76, allowing a layer ofice to form along the cooled ice forming plate 76, and rocking the iceforming plate 76 while the water is freezing. Once the clear ice 98 isformed, the ice 98 is harvested into a storage bin 64. From the storagebin 64, the clear ice 98 is available for dispensing to a user.

In certain embodiments, multiple steps may occur simultaneously. Forexample, the ice forming plate 76 may be cooled and rocked while thewater is being dispensed onto the ice forming plate 76. However, inother embodiments, the ice forming plate 76 may be held stationary whilewater is dispensed, and rocked only after an initial layer of ice 98 hasformed on the ice forming plate 76. Allowing an initial layer of ice toform prior to initiating a rocking movement prevents flash freezing ofthe ice or formation of a slurry, which improves ice clarity.

In one aspect of the invention, as shown in FIGS. 4-12, an ice maker 52includes a twist harvest ice maker 52 which utilizes oscillation duringthe freezing cycle, variations in conduction of materials, a cold air182 flow to remove heat from the heat sink 104 and cool the underside ofthe ice forming plate 76 and a warm air 174 flow to produce clear icepieces 98. In this embodiment, one driving motor 112, 114 is typicallypresent on each end of the ice tray 70.

In the embodiment depicted in FIGS. 4-12, an ice tray 70 is horizontallysuspended across and pivotally coupled to stationary support members 72within an ice maker housing 54. The housing 54 may be integrally formedwith a door liner 73, and include the door liner 73 with a cavity 74therein, and a cover 75 pivotally coupled with a periphery of the cavity74 to enclose the cavity 74. The ice tray 70, as depicted in FIG. 4,includes an ice forming plate 76, with a top surface 78 and a bottomsurface 80. Typically, a containment wall 82 surrounds the top surface78 of the ice forming plate 76 and extends upwards around the peripherythereof. The containment wall 82 is configured to retain water on thetop surface 78 of the ice forming plate 76. A median wall 84 extendsorthogonally from the top surface 78 of the ice forming plate 76 along atransverse axis thereof, dividing the ice tray 70 into at least tworeservoirs 86, 88, with a first reservoir 86 defined between the medianwall 84 and a first sidewall 90 of the containment wall 82 and a secondreservoir 88 defined between the median wall 84 and a second sidewall 92of the containment wall 82, which is generally opposing the firstsidewall 90 of the containment wall 82. Further dividing walls 94 extendgenerally orthogonally from the top surface 78 of the ice forming plate76 generally perpendicularly to the median wall 84. These dividing walls94 further separate the ice tray 70 into an array of individualcompartments 96 for the formation of clear ice pieces 98.

A grid 100 is provided, as shown in FIGS. 4-12B which forms the medianwall 84 the dividing walls 94, and an edge wall 95. As furtherdescribed, the grid 100 is separable from the ice forming plate 76 andthe containment wall 82, and is preferably resilient and flexible tofacilitate harvesting of the clear ice pieces 98.

As shown in FIG. 6, a thermoelectric device 102 is physically affixedand thermally connected to the bottom surface 80 of the ice formingplate 76 to cool the ice forming plate 76, and thereby cool the wateradded to the top surface 78 of the ice forming plate 76. Thethermoelectric device 102 is coupled to a heat sink 104, and transfersheat from the bottom surface 80 of the ice forming plate 76 to the heatsink 104 during formation of clear ice pieces 98. One example of such adevice is a thermoelectric plate which can be coupled to a heat sink104, such as a Peltier-type thermoelectric cooler.

As shown in FIGS. 5 and 7A-7F, in one aspect the ice tray 70 issupported by and pivotally coupled to a rocker frame 110, with anoscillating motor 112 operably connected to the rocker frame 110 and icetray 70 at one end 138, and a harvest motor 114 operably connected tothe ice tray 70 at a second end 142.

The rocker frame 110 is operably coupled to an oscillating motor 112,which rocks the frame 110 in a back and forth motion, as illustrated inFIGS. 7A-7F. As the rocker frame 110 is rocked, the ice tray 70 isrocked with it. However, during harvesting of the clear ice pieces 98,the rocker frame remains 110 stationary and the harvest motor 114 isactuated. The harvest motor 114 rotates the ice tray 70 approximately120°, as shown in FIGS. 12A and 12B, until a stop 116, 118 between therocker frame 110 and ice forming plate 76 prevents the ice forming plate76 and containment wall 82 from further rotation. Subsequently, theharvest motor 114 continues to rotate the grid 100, twisting the grid100 to release clear ice pieces 98, as illustrated in FIG. 12B.

Having briefly described the overall components and their orientation inthe embodiment depicted in FIGS. 4-12B, and their respective motion, amore detailed description of the construction of the ice maker 52 is nowpresented.

The rocker frame 110 in the embodiment depicted in FIGS. 4-12B includesa generally open rectangular member 120 with a longitudinally extendingleg 122, and a first arm 124 at the end 138 adjacent the oscillatingmotor 112 and coupled to a rotary shaft 126 of the oscillating motor 112by a metal spring clip 128. The oscillating motor 112 is fixedly securedto a stationary support member 72 of the refrigerator 50. The frame 110also includes a generally rectangular housing 130 at the end 142opposite the oscillating motor 112 which encloses and mechanicallysecures the harvest motor 114 to the rocker frame 110. This can beaccomplished by snap-fitting tabs and slots, threaded fasteners, or anyother conventional manner, such that the rocker frame 110 securely holdsthe harvest motor 114 coupled to the ice tray 70 at one end 138, and theopposite end 142 of the ice tray 70 via the arm 124. The rocker frame110 has sufficient strength to support the ice tray 70 and the clear icepieces 98 formed therein, and is typically made of a polymeric materialor blend of polymeric materials, such as ABS (acrylonitrile, butadiene,and styrene), though other materials with sufficient strength are alsoacceptable.

As shown in FIG. 5, the ice forming plate 76 is also generallyrectangular. As further shown in the cross-sectional view depicted inFIG. 6, the ice forming plate 76 has upwardly extending edges 132 aroundits exterior, and the containment wall 82 is typically integrally formedover the upwardly extending edges 132 to form a water-tight assembly,with the upwardly extending edge 132 of the ice forming plate 76embedded within the lower portion of the container wall 82. The iceforming plate 76 is preferably a thermally conductive material, such asmetal. As a non-limiting example, a zinc-alloy is corrosion resistantand suitably thermally conductive to be used in the ice forming plate76. In certain embodiments, the ice forming plate 76 can be formeddirectly by the thermoelectric device 102, and in other embodiments theice forming plate 76 is thermally linked with thermoelectric device 102.The containment walls 82 are preferably an insulative material,including, without limitation, plastic materials, such as polypropylene.The containment wall 82 is also preferably molded over the upstandingedges 132 of the ice forming plate 76, such as by injection molding, toform an integral part with the ice forming plate 76 and the containmentwall 82. However, other methods of securing the containment wall 82,including, without limitation, mechanical engagement or an adhesive, mayalso be used. The containment wall 82 may diverge outwardly from the iceforming plate 76, and then extend in an upward direction which issubstantially vertical.

The ice tray 70 includes an integral axle 134 which is coupled to adrive shaft 136 of the oscillating motor 112 for supporting a first endof the ice tray 138. The ice tray 70 also includes a second pivot axle140 at an opposing end 142 of the ice tray 70, which is rotatablycoupled to the rocker frame 110.

The grid 100, which is removable from the ice forming plate 76 andcontainment wall 82, includes a first end 144 and a second end 146,opposite the first end 144. Where the containment wall 82 diverges fromthe ice freezing plate 76 and then extends vertically upward, the grid100 may have a height which corresponds to the portion of thecontainment wall 82 which diverges from the ice freezing plate 76. Asshown in FIG. 4, the wall 146 on the end of the grid 100 adjacent theharvest motor 114 is raised in a generally triangular configuration. Apivot axle 148 extends outwardly from the first end of the grid 144, anda cam pin 150 extends outwardly from the second end 146 of the grid 100.The grid 100 is preferably made of a flexible material, such as aflexible polymeric material or a thermoplastic material or blends ofmaterials. One non-limiting example of such a material is apolypropylene material.

The containment wall 82 includes a socket 152 at its upper edge forreceiving the pivot axle 148 of the grid 100. An arm 154 is coupled to adrive shaft 126 of the harvest motor 114, and includes a slot 158 forreceiving the cam pin 150 formed on the grid 100.

A torsion spring 128 typically surrounds the internal axle 134 of thecontainment wall 82, and extends between the arm 154 and the containmentwall 82 to bias the containment wall 82 and ice forming plate 76 in ahorizontal position, such that the cam pin 150 of the grid 100 is biasedin a position of the slot 158 of the arm 154 toward the ice formingplate 76. In this position, the grid 100 mates with the top surface 78of the ice forming plate 76 in a closely adjacent relationship to formindividual compartments 96 that have the ice forming plate defining thebottom and the grid defining the sides of the individual ice formingcompartments 96, as seen in FIG. 6.

The grid 100 includes an array of individual compartments 96, defined bythe median wall 84, the edge walls 95 and the dividing walls 94. Thecompartments 96 are generally square in the embodiment depicted in FIGS.4-12B, with inwardly and downwardly extending sides. As discussed above,the bottoms of the compartments 96 are defined by the ice forming plate76. Having a grid 100 without a bottom facilitates in the harvest of icepieces 98 from the grid 100, because the ice piece 98 has already beenreleased from the ice forming plate 76 along its bottom when the iceforming piece 98 is harvested. In the shown embodiment, there are eightsuch compartments. However, the number of compartments 96 is a matter ofdesign choice, and a greater or lesser number may be present within thescope of this disclosure. Further, although the depiction shown in FIG.4 includes one median wall 84, with two rows of compartments 96, two ormore median walls 84 could be provided.

As shown in FIG. 6, the edge walls 95 of the grid 100 as well as thedividing walls 94 and median wall 84 diverge outwardly in a triangularmanner, to define tapered compartments 96 to facilitate the removal ofice pieces 98 therefrom. The triangular area 162 within the wallsections may be filled with a flexible material, such as a flexiblesilicone material or EDPM (ethylene propylene diene monomer M-classrubber), to provide structural rigidity to the grid 100 while at thesame time allowing the grid 100 to flex during the harvesting step todischarge clear ice pieces 98 therefrom.

The ice maker 52 is positioned over an ice storage bin 64. Typically, anice bin level detecting arm 164 extends over the top of the ice storagebin 64, such that when the ice storage bin 64 is full, the arm 164 isengaged and will turn off the ice maker 52 until such time as additionalice 98 is needed to fill the ice storage bin 64.

FIGS. 7A-7F and FIGS. 12A-12B illustrate the ice making process of theice maker 52. As shown in FIG. 7A, water is first dispensed into the icetray 70. The thermoelectric cooler devices 102 are actuated andcontrolled to obtain a temperature less than freezing for the iceforming plate 76. One preferred temperature for the ice forming plate 76is a temperature of from about −8° F. to about −15° F., but moretypically the ice forming plate is at a temperature of about −12° F. Atthe same time, approximately the same time, or after a sufficient timeto allow a thin layer of ice to form on the ice forming plate, theoscillating motor 12 is actuated to rotate the rocker frame 110 and icecube tray 70 carried thereon in a clockwise direction, through an arc offrom about 20° to about 40°, and preferably about 30°. The rotation alsomay be reciprocal at an angle of about 40° to about 80°. The water inthe compartments 96 spills over from one compartment 96 into an adjacentcompartment 96 within the ice tray 70, as illustrated in FIG. 7C. Thewater may also be moved against the containment wall 82, 84 by theoscillating motion. Subsequently, the rocker frame is rotated in theopposite direction, as shown in FIG. 7D, such that the water spills fromone compartment 96 into and over the adjacent compartment 96. Themovement of water from compartment 96 to adjacent compartment 96 iscontinued until the water is frozen, as shown in FIGS. 7E and 7F.

As the water cascades over the median wall 84, air in the water isreleased, reducing the number of bubbles in the clear ice piece 98formed. The rocking may also be configured to expose at least a portionof the top layer of the clear ice pieces 98 as the liquid water cascadesto one side and then the other over the median wall 84, exposing the topsurface of the ice pieces 98 to air above the ice tray. The water isalso frozen in layers from the bottom (beginning adjacent the topsurface 78 of the ice forming plate 76, which is cooled by thethermoelectric device 102) to the top, which permits air bubbles toescape as the ice is formed layer by layer, resulting in a clear icepiece 98.

As shown in FIGS. 8-11, to promote clear ice production, the temperaturesurrounding the ice tray 70 can also be controlled. As previouslydescribed, a thermoelectric device 102 is thermally coupled or otherwisethermally engaged to the bottom surface 80 of the ice forming plate 76to cool the ice forming plate 76. In addition to the direct cooling ofthe ice forming plate 76, heat may be applied above the water containedin the ice tray 70, particularly when the ice tray 70 is being rocked,to cyclically expose the top surface of the clear ice pieces 98 beingformed.

As shown in FIGS. 8 and 9, heat may be applied via an air intake conduit166, which is operably connected to an interior volume of the housing168 above the ice tray 70. The air intake conduit 166 may allow theintake of warmer air 170 from a refrigerated compartment 60 or theambient surroundings 171, and each of these sources of air 60, 171provide air 170 which is warmer than the temperature of the ice formingplate 176. The warmer air 170 may be supplied over the ice tray 70 in amanner which is sufficient to cause agitation of the water retainedwithin the ice tray 70, facilitating release of air from the water, ormay have generally laminar flow which affects the temperature above theice tray 70, but does not agitate the water therein. A warm air exhaustconduit 172, which also communicates with the interior volume 168 of thehousing 54, may also be provided to allow warm air 170 to be circulatedthrough the housing 54. The other end of the exhaust conduit 172 maycommunicate with the ambient air 171, or with a refrigerator compartment60. As shown in FIG. 8, the warm air exhaust conduit 172 may be locatedbelow the intake conduit 166. To facilitate flow of the air 170, an airmovement device 174 may be coupled to the intake or the exhaust conduits166, 172. Also as shown in FIG. 8, when the housing 54 of the ice maker52 is located in the door 56 of the appliance 50, the intake conduit 166and exhaust conduit 172 may removably engage a corresponding inlet port176 and outlet port 178 on an interior sidewall 180 of the appliance 50when the appliance door 56 is closed.

Alternatively, the heat may be applied by a heating element (not shown)configured to supply heat to the interior volume 168 of the housing 54above the ice tray 70. Applying heat from the top also encourages theformation of clear ice pieces 98 from the bottom up. The heatapplication may be deactivated when ice begins to form proximate theupper portion of the grid 100, so that the top portion of the clear icepieces 98 freezes.

Additionally, as shown in FIGS. 8-11, to facilitate cooling of the iceforming plate 76, cold air 182 is supplied to the housing 54 below thebottom surface 80 of the ice forming plate 76. A cold air inlet 184 isoperably connected to an intake duct 186 for the cold air 182, which isthen directed across the bottom surface 80 of the ice forming plate 76.The cold air 182 is then exhausted on the opposite side of the iceforming plate 76.

As shown in FIG. 11, the ice maker is located within a case 190 (or thehousing 54), and a barrier 192 may be used to seal the cold air 182 tothe underside of the ice forming plate 76, and the warm air 170 to thearea above the ice tray 70. The temperature gradient that is produced bysupplying warm air 170 to the top of the ice tray 70 and cold air 182below the ice tray 70 operates to encourage unidirectional formation ofclear ice pieces 98, from the bottom toward the top, allowing the escapeof air bubbles.

As shown in FIGS. 12A-12B, once clear ice pieces are formed, the icemaker 52, as described herein, harvests the clear ice pieces 98,expelling the clear ice pieces 98 from the ice tray 70 into the icestorage bin 64. To expel the ice 98, the harvest motor 114 is used torotate the ice tray 70 and the grid 100 approximately 120°. This invertsthe ice tray 70 sufficiently that a stop 116, 118 extending between theice forming plate 76 and the rocker frame 110 prevents further movementof the ice forming plate 76 and containment walls 82. Continued rotationof the harvest motor 114 and arm 154 overcomes the tension of the springclip 128 linkage, and as shown in FIG. 12B, the grid 100 is furtherrotated and twisted through an arc of about 40° while the arm 154 isdriven by the harvest motor 114 and the cam pin 150 of the grid 100slides along the slot 158 from the position shown in FIG. 12A to theposition shown in FIG. 12B. This movement inverts and flexes the grid100, and allows clear ice pieces 98 formed therein to drop from the grid100 into an ice bin 64 positioned below the ice maker 52.

Once the clear ice pieces 98 have been dumped into the ice storage bin64, the harvest motor 114 is reversed in direction, returning the icetray 7 to a horizontal position within the rocker frame 110, which hasremained in the neutral position throughout the turning of the harvestmotor 114. Once returned to the horizontal starting position, anadditional amount of water can be dispensed into the ice tray 70 to forman additional batch of clear ice pieces.

FIG. 13 depicts a control circuit 198 which is used to control theoperation of the ice maker 52. The control circuit 198 is operablycoupled to an electrically operated valve 200, which couples a watersupply 202 and the ice maker 52. The water supply 202 may be a filteredwater supply to improve the quality (taste and clarity for example) ofclear ice piece 98 made by the ice maker 52, whether an external filteror one which is built into the refrigerator 50. The control circuit 198is also operably coupled to the oscillation motor 112, which in oneembodiment is a reversible pulse-controlled motor. The output driveshaft 136 of the oscillating motor 112 is coupled to the ice maker 52,as described above. The drive shaft 136 rotates in alternatingdirections during the freezing of water in the ice maker 52. The controlcircuit 198 is also operably connected to the thermoelectric device 102,such as a Peltier-type thermoelectric cooler in the form ofthermoelectric plates. The control circuit 198 is also coupled to theharvest motor 114, which inverts the ice tray 70 and twists the grid 100to expel the clear ice pieces 98 into the ice bin 64.

The control circuit 198 includes a microprocessor 204 which receivestemperature signals from the ice maker 52 in a conventional manner byone or more thermal sensors (not shown) positioned within the ice maker52 and operably coupled to the control circuit 198. The microprocessor204 is programmed to control the water dispensing valve 200, theoscillating motor 112, and the thermoelectric device 114 such that thearc of rotation of the ice tray 70 and the frequency of rotation iscontrolled to assure that water is transferred from one individualcompartment 96 to an adjacent compartment 96 throughout the freezingprocess at a speed which is harmonically related to the motion of thewater in the freezer compartments 96.

The water dispensing valve 200 is actuated by the control circuit 198 toadd a predetermined amount of water to the ice tray 70, such that theice tray 70 is filled to a specified level. This can be accomplished bycontrolling either the period of time that the valve 200 is opened to apredetermined flow rate or by providing a flow meter to measure theamount of water dispensed.

The controller 198 directs the frequency of oscillation w to a frequencywhich is harmonically related to the motion of the water in thecompartments 96, and preferably which is substantially equal to thenatural frequency of the motion of the water in the trays 70, which inone embodiment was about 0.4 to 0.5 cycles per second. The rotationalspeed of the oscillating motor 112 is inversely related to the width ofthe individual compartments 96, as the width of the compartments 96influences the motion of the water from one compartment to the adjacentcompartment. Therefore, adjustments to the width of the ice tray 70 orthe number or size of compartments 96 may require an adjustment of theoscillating motor 112 to a new frequency of oscillation w.

The waveform diagram of FIG. 14 illustrates the amplitude of the wavesin the individual compartments 96 versus the frequency of oscillationprovided by the oscillating motor 112. In FIG. 14 it is seen that thenatural frequency of the water provides the highest amplitude. A secondharmonic of the frequency provides a similarly high amplitude of watermovement. It is most efficient to have the amplitude of water movementat least approximate the natural frequency of the water as it moves fromone side of the mold to another. The movement of water from oneindividual compartment 96 to the adjacent compartment 96 is continueduntil the thermal sensor positioned in the ice tray 70 at a suitablelocation and operably coupled to the control circuit 198 indicates thatthe water in the compartment 96 is frozen.

After the freezing process, the voltage supplied to the thermoelectricdevice 102 may optionally be reversed, to heat the ice forming plate 76to a temperature above freezing, freeing the clear ice pieces 98 fromthe top surface 78 of the ice forming plate 76 by melting a portion ofthe clear ice piece 98 immediately adjacent the top surface 78 of theice forming plate 76. This allows for easier harvesting of the clear icepieces 98. In the embodiment described herein and depicted in FIG. 13,each cycle of freezing and harvesting takes approximately 30 minutes.

In another aspect of the ice maker 210, as shown in FIGS. 15-33, an icemaker 120 includes a twist harvest ice maker, which utilizes oscillationduring the freezing cycle, variations in thermal conduction ofmaterials, and a cold air 370 flow during the freezing cycle to produceclear ice pieces 236. The ice maker in FIGS. 15-33 also has two drivingmotors 242, 244 on one end 246 of the ice maker 210. The ice maker 210as shown in FIGS. 15-33 could also be modified to include, for example,a warm air flow during the freezing cycle, or to include other featuresdescribed with respect to other aspects or embodiments described herein,such as similar materials of construction or rotation amounts.

The ice maker 210 depicted in FIGS. 15-33 is horizontally suspendedwithin a housing 212, and located above an ice storage bin (not shown inFIGS. 15-33). The ice maker 210 includes an ice tray 218 having an iceforming plate 220 with a top surface 222 and a bottom surface 224, and acontainment wall 226 extending upwardly around the perimeter of the iceforming plate 220. A median wall 228 and dividing walls 230 extendorthogonally upward from the top surface 222 of the ice forming plate220 to define the grid 232, having individual compartments 234 for theformation of clear ice pieces 236.

As shown in FIG. 15, a thermoelectric device 238 is thermally connectedto the bottom surface 224 of the ice forming plate 220, and conductors240 are operably attached to the thermoelectric device 238 to providepower and a control signal for the operation of the thermoelectricdevice 238. Also, as shown in the embodiment depicted in FIG. 15, anoscillating motor 242 and a harvest motor 244 are both located proximalto a first end 246 of the ice tray 218.

The ice tray 218 and thermoelectric device 238 are typically disposedwithin a shroud member 250 having a generally cylindrical shape alignedwith the transverse axis of the ice tray 218. The shroud member 250 istypically an incomplete cylinder, and is open over the top of the icetray 218. The shroud 250 includes at least partially closed end walls252 surrounding the first end 246 of the ice tray 218 and a second end248 of the ice tray 218. The shroud member 250 typically abuts theperiphery of the containment wall 226 to separate a first air chamber254 above the ice tray 218 and a second air chamber 256 below the icetray 218. The housing 212 further defines the first air chamber 254above the ice tray 218.

As illustrated in FIGS. 16-18, a generally U-shaped bracket 258 extendsfrom the first end 246 of the ice tray 218, and includes a cross bar 260and two connecting legs 262, one at each end of the cross bar 260. Aflange 264 extends rearwardly from the cross bar 260, and a roundedopening 266 is provided through the center of the cross bar 260, which,as best shown in FIGS. 17-18 receives a cylindrical linkage piece 268with a keyed opening 270 at one end thereof, and a generally roundedopening 272 at the other end thereof. The keyed opening 270 accepts thekeyed drive shaft 274 of the harvest motor 244, and the rounded opening272 accepts an integral axle 276 extending along the transverse axisfrom the ice tray 218.

As shown in FIG. 16, a harvest arm 278 is disposed between the first end246 of the ice tray 218 and the cross bar 260 of the bracket 258. Theharvest arm 278, as best shown in FIG. 17, includes a slot 280 forreceiving a cam pin 328 formed on the grid 232, an opening 282 forreceiving the cylindrical linkage piece 268 on the opposite end of theharvest arm 278, and a spring stop 284 adjacent the opening 282. Theharvest arm 278 is biased in a resting position by the spring clip 286,as shown in FIGS. 17-18, which is disposed between the harvest arm 278and the cross bar 260, with a first free end 288 of the spring clip 286seated against the spring stop 284 of the harvest arm 278 and a secondfree end 290 of the spring clip 286 seated against the flange 264 of thecross bar 260.

Also as shown in FIG. 16, the harvest motor 244 is affixed to a framemember 292, with the keyed drive shaft 274 extending from the harvestmotor 244 toward the keyed opening 270 of the cylindrical linkage 268.When assembled, the keyed drive shaft 274 fits within the keyed opening270. The frame member 292 further incorporates a catch 294, whichengages with the ice tray 218 during the harvesting step to halt therotational movement of the ice forming plate 220 and containment wall226.

FIGS. 17 and 18 provide additional detail relating to the operableconnections of the harvest motor 244 and the oscillating motor 242. Asbest shown in FIG. 17, the oscillation motor 242 is affixed to a framemember 292 via a mounting 296. The drive shaft 297 of the oscillationmotor 242, directly or indirectly, drives rotation of the frame member292 back and forth in an alternating rotary motion during the icefreezing process. As shown in FIGS. 17 and 20, the oscillating motor 242has a motor housing 298 which includes flanges 300 with holes 302therethrough for mounting of the oscillating motor 242 to a stationarysupport member (not shown in FIGS. 15-33).

During ice freezing, the harvest motor 244 is maintained in a lockedposition, such that the keyed drive shaft 274 of the harvest motor 244,which is linked to the ice tray 218, rotates the ice tray 218 in thesame arc that the frame member 292 is rotated by the oscillation motor242. As described above, an arc from about 20° to about 40°, andpreferably about 30°, is preferred for the oscillation of the ice tray218 during the ice freezing step. During the harvest step, as furtherdescribed below, the oscillating motor 242 is stationary, as is theframe member 292. The harvest motor 244 rotates its keyed drive shaft274, which causes the ice tray 218 to be inverted and the ice 236 to beexpelled. FIG. 19 further illustrates the positioning of the oscillatingmotor 242, the frame member 292 and the shroud 250.

It is believed that a single motor could be used in place of theoscillating motor 242 and harvest motor 244 with appropriate gearingand/or actuating mechanisms.

An ice bin level sensor 30 is also provided, which detects the level ofice 236 in the ice storage bin (not shown in FIGS. 15-33), and providesthis information to a controller (not shown in FIGS. 15-33) to determinewhether to make additional clear ice pieces 236.

To facilitate air movement, as shown in FIG. 19, the shroud 250 has afirst rectangular slot 312 therein. As further illustrated in FIGS.22-23 and 31, a second rectangular slot 314 is provided in acorresponding location on the opposing side of the shroud 250. Therectangular slots 312, 314 in the shroud 250 permit air flow through thesecond chamber 256, as further described below and as shown in FIGS.22-23 and 31.

As shown in FIGS. 21 and 22, the shroud 250 encompasses the ice tray218, including the ice forming plate 220, the containment wall 226,which is preferably formed over an upstanding edge 316 of the iceforming plate 220, and the grid 232. The shroud 250 has a semicircularcross sectional area, and abuts the top perimeter of the containmentwall 226. The shroud 250 also encloses the thermoelectric device 102which cools the ice forming plate 220, and a heat sink 318 associatedtherewith.

The ice tray 218 is also shown in detail in FIG. 22. The ice tray 218includes the ice forming plate 220, with upstanding edges 316 around itsperimeter, and the containment wall 286 formed around the upstandingedges 316 to create a water-tight barrier around the perimeter of theice forming plate 220.

The arrangement of the grid 232, and the materials of construction forthe grid 232 as described herein facilitate the “twist release”capability of the ice tray 218. The features described below allow thegrid 232 to be rotated at least partially out of the containment wall226, and to be twisted, thereby causing the clear ice pieces 236 to beexpelled from the grid 232. As shown in FIGS. 23-24, the grid 232extends generally orthogonally upward from the top surface 222 of theice forming plate 220. A flexible, insulating material 320 may beprovided between adjacent walls of the grid 232. The grid 232 also has agenerally raised triangular first end 322, adjacent the motor 242, 244connections and a generally raised triangular second end 324, oppositethe first end 322. The grid 232 has a pivot axle 326 extending outwardlyfrom each of the raised triangular ends 322, 324, and not aligned alongthe transverse axis about which the ice tray 218 is rotated duringoscillation. The grid 232 also has a cam pin 328 extending outwardlyfrom each peak of the raised triangular ends 322, 324. The grid 232 mayalso include edge portions 330, which are adjacent the side containmentwalls 226 when the grid 232 is placed therein. As shown in FIGS. 21 and23, the pivot axles 326 are received within generally round apertures332 on the adjacent containment walls 226. The cam pin 328 at the firstend 322 is received in the slot 280 in the harvest arm 278, and the campin 328 at the second end 324 is received in a socket 334 in thecontainment wall 226.

The thermoelectric device 102, as depicted in the embodiment shown inFIGS. 23 and 26 includes a thermoelectric conductor 336 that is attachedto a thermoconductive plate 340 on one side 338 and a heat sink 318 on asecond side 342, having heat sink fins 344. The thermoconductive plate340 optionally has openings 346 therein for the thermoelectric conductor336 to directly contact the ice forming plate 220. The thermoconductiveplate 340, thermoelectric conductor 336 and heat sink 318 are fastenedto the ice tray 218, along the bottom surface 224 of the ice formingplate 220, through holes 348 provided on the thermoconductive plate 340and the heat sink 318. The thermoelectric conductor 336 transfers heatfrom the thermoconductive plate 340 to the heat sink 318 during thefreezing cycle, as described above.

The second end 248 of the containment wall 226 and shroud 250 (the sideaway from the motors 242, 244) are shown in FIG. 25. A second pivot axle350 extends outwardly from the containment wall 226, allowing arotatable connection with the housing 212.

As shown in FIGS. 27-30, the ice tray 218, partially enclosed within theshroud 250, is suspended across an interior volume 352 of the housing312. The shroud 250 aids in directing the air flow as described belowfor formation of clear ice pieces 236. The housing 212, as shown in FIG.27, includes a barrier 354 to aid in separation of the first air chamber254 and the second air chamber 256, so that the second air chamber 256can be maintained at a temperature that is colder than the first airchamber 254. The air temperature of the first chamber 254 is preferablyat least 10 degrees Fahrenheit warmer than the temperature of the secondchamber 256.

When installed in the housing 212, the shroud member 250 is configuredto maintain contact with the barrier 354 as the ice tray 218 isoscillated during ice formation. An air intake duct member 356 having aduct inlet 358 and a duct outlet 360, with the duct outlet 360 adaptedto fit over the surface of the shroud 250 and maintain contact with theshroud 250 as the shroud 250 rotates, is also fitted into the housing212. The shaped opening of the duct outlet 260 is sufficiently sized toallow a fluid connection between the duct outlet 260 and the firstrectangular slot 312 even as the ice tray 218 and shroud 250 arereciprocally rotated during the freezing cycle. The rectangular slot 312restricts the amount of air 356 entering the shroud 250, such that theamount of air 370 remains constant even as the ice tray 218 is rotated.An exhaust duct 362 is optionally provided adjacent the secondrectangular opening 314, to allow air 370 to escape the housing 212. Theexhaust duct 362 has a duct intake 364 which is arranged to allowcontinuous fluid contact with the second rectangular slot 314 as the icetray 218 and shroud 250 are rocked during the ice formation stage. Theexhaust duct 362 also has a duct outlet 366 which is sufficiently sizedto allow the clear ice pieces 236 to fall through the duct outlet 366and into the ice bin 64 during the harvesting step.

An air flow path 368 is created that permits cold air 370 to travel fromthe duct inlet 358, to the duct outlet 360, into the first rectangularslot 312 in the shroud, across the heat sink fins 344, which arepreferably a conductive metallic material, and out of the secondrectangular slot 314 in the shroud 250 into the exhaust duct 362. Asshown in FIG. 30, baffles 372 may also be provided in the intake ductmember 356 to direct the air flow path 368 toward the heat sink fins344. The barrier 354 prevents the cold air 370 that is exhausted throughthe second rectangular slot 314 from reaching the first air chamber 254.The flow of cold air 370 aids in removing heat from the heat sink 344.

One example of an air flow path 368 enabled by the air intake duct 356and exhaust duct 362 is shown in FIGS. 31A-31C. As shown in FIGS.31A-31B, as the tray 218 is rocked, the rectangular slots 312, 314 inthe shroud 250 remain in fluid connection with the air intake ductoutlet 360 and the exhaust duct inlet 364. Therefore, the air flow path368 is not interrupted by the oscillation of the ice tray 218 during thefreezing step. Also, as shown in FIGS. 32A-32B, as the clear ice pieces236 are harvested from the ice tray 218, the clear ice pieces 236 arepermitted to fall through the exhaust duct 362 into the ice storage bin.During the harvest cycle as illustrated in FIGS. 32A-32B, the fluid path368 for cooling air is not continuous. However, the shroud 250 continuesto generally separate the first air chamber 254 from the second airchamber 256.

FIGS. 33A-33D depict the rotation of the ice tray 218 and the grid 232during the harvest step. As the harvest motor 244 rotates the ice tray218 to an inverted position, as shown in FIG. 33B, the cam pin 328extending from the second end 324 of the grid 232 travels within thecontainment wall socket 334 to the position farthest from the iceforming plate 220. As the harvest motor 244 continues to drive rotationof the arm 278, the rotation of the ice forming plate 220 is halted by acatch 297, and the cam pin 328 extending from the first end 322 of thegrid 232 continues to travel the length of the slot 280 in the harvestarm 278 away from the ice forming plate 220. As the length of the slot280 is longer than the socket 334, the grid 232 will be twisted,expelling the clear ice pieces 236.

In general, the ice makers 52, 210 described herein create clear icepieces 98, 236 through the formation of ice in a bottom-up manner, andby preventing the capture of air bubbles or facilitating their releasefrom the water. The clear ice pieces 98, 236 are formed in a bottom-upmanner by cooling the ice tray 70, 218 from the bottom, with or withoutthe additional benefit of cold air flow to remove heat from the heatsink 104, 318. The use of insulative materials to form the grid 100, 232and containment walls 82, 226, such that the cold temperature of the iceforming plate 76, 220 is not transmitted upward through the individualcompartments 96, 234 for forming ice also aids in freezing the bottomlayer of ice first. A warm air flow over the top of the clear ice pieces98, 236 as they are forming can also facilitate the unidirectionalfreezing. Rocking aids in the formation of clear ice pieces 98, 236 inthat it causes the release of air bubbles from the liquid as the liquidcascades over the median wall 84, 228, and also in that it encouragesthe formation of ice in successive thin layers, and, when used inconnection with warm air flow, allows exposure of the surface of theclear ice piece 98, 236 to the warmer temperature.

The ice makers described herein also include features permitting theharvest of clear ice pieces 98, 236, including the harvest motor 114,244, which at least partially inverts the ice tray 70, 218, and thencauses the release and twisting of the grid 100, 232 at least partiallyout of the containment wall 84, 226 to expel clear ice pieces 98, 236.The ice forming plate 76, 220 and associated thermoelectric device 102,238 can also be used to further facilitate harvest of clear ice pieces98, 236 by reversing polarity to heat the ice forming plate 76, 220 and,therefore, heat the very bottom portion of the clear ice pieces 98, 236such that the clear ice pieces 98, 236 are easily released from the iceforming plate 76, 220 and removed from contacting the ice forming plate76, 220.

FIGS. 34, 35A and 35B illustrate additional potential embodiments forthe ice maker 378, 402. As illustrated by FIGS. 34 and 35, alternatearrangements for the ice tray, the cooling mechanism, and the rockingmechanism also permit the formation of clear ice (not shown in FIGS.34-35) via a rocking mechanism. In each of the additional embodiments, apredetermined volume of water is added to the ice maker 378, 402, andthe lower surface 382, 404 of the ice maker 378, 402 is cooled such thatthe ice is formed unidirectionally, from the bottom to the top. Therocking motion facilitates formation of the ice in a unidirectionalmanner, allowing the air to easily escape, resulting in fewer bubbles tonegatively affect the clarity of the clear ice piece that is formed.

As shown in FIG. 34, an ice forming tray 380 may include a central iceforming plate 382, having a bottom surface 384, which is cooled by athermoelectric plate (not shown) having a heat sink 386, and a topsurface 388, which is adapted to hold water, with reservoirs 390, 392 ateither end and a containment wall 394 extending upwards around theperimeter of the ice forming plate 382 and reservoirs 390, 392. As shownin FIG. 34, the ice maker 378 may also be rocked by alternatemeans/devices than the rotary oscillating motors previously described.In the embodiment depicted in FIG. 34, the ice maker 378 is rocked on arocking table 396, with a pivot axle 398 through the middle of the iceforming plate 382, and at least one actuating mechanism 400 raising andlowering the end of the ice forming plate 382 and the first and secondreservoirs 390, 392 in sequence. As the tray 380 is rocked, water flowsover the central ice forming plate 382 and into a first reservoir 390 onone end. As the tray 380 is rocked in the opposite direction, the waterflows over the ice forming plate 382 and into the second reservoir 392on the other end. As the water is flowing over the ice forming plate382, the ice forming plate 382 is being cooled, to facilitate formationof at least one clear ice piece. In this embodiment, a large clear icepiece may be formed in the ice forming plate 382. Alternatively, a gridor other shaped divider (not shown) may be provided on the ice formingplate 382, such that water is frozen into the desired shapes on the iceforming plate 382 and water cascades over the divided segments tofurther release air therefrom.

As shown in FIGS. 35A and 35B, an alternative cooling mechanism and iceforming plate 404 may also be used. Here, an ice forming plate 404 withformed ice wells 406 therein is provided. The wells 406 are capable ofcontaining water for freezing. Each of the wells 406 is defined alongits bottom by a bottom surface 408, which may or may not be flat, andits sides by at least one wall 410 extending upwardly from the bottomsurface 408. Each of the at least one walls 410 includes an interiorsurface 412, which is facing the ice well 406 and a top surface 414. Thebottom surface 408 and interior surfaces 412 together make up an iceforming compartment 416. An insulating material is applied to the upperportion of the ice wells 406 and the top surface of the walls to form aninsulating layer 418.

The ice forming plate 404 is preferably formed of a thermally conductivematerial such as a metallic material, and the insulating layer 418 ispreferably an insulator such as a polymeric material. One non-limitingexample of a polymeric material suitable for use as an insulator is apolypropylene material. The insulating layer 418 may be adhered to theice forming plate 404, molded onto the ice forming plate 404,mechanically engaged with the ice forming plate 404, overlayed over theplate 404 without attaching, or secured in other removable ornon-removable ways to the ice forming plate 404. The insulating layer418 may also be an integral portion of the ice forming plate 76material. This construction, using an insulating layer 418 proximate thetop of the ice wells 406, facilitates freezing of the clear ice piece 98from the top surface 78 of the ice forming plate 76 upward.

An evaporator element 420 is thermally coupled with the ice formingplate 404, typically along the outside of the ice wells 406, oppositethe ice forming compartments 416, and the evaporator element 420 extendsalong a transverse axis 422 of the ice forming plate 404. The evaporatorelement 420 includes a first coil 424 proximate a first end 426 of theice forming plate 404 and a second coil 428 proximate the second end 403of the ice forming plate 404.

The ice forming plate 404 and insulating layer 418 as shown in FIG. 35Acan also be used in an automatic oscillating ice maker 402 as a twistingmetal tray, as described above. When so used, the first and second coils424, 428 are configured to permit the evaporator element 420 to flexwhen a drive body (not shown in FIG. 35A) reciprocally rotates the iceforming plate 404. Alternatively, thermoelectric plates (not shown inFIG. 35A) could also be used to cool the ice forming plate 404 from thebottom. In use, a predetermined volume of water is added to the icewells through a fluid line (not shown in FIG. 35A) positioned above theice forming plate 404. The bottom surface 408 of the formed ice wells406 is cooled by the evaporator element 420, and a drive body (not shownin FIG. 35A) causes rotation of the ice forming plate 404 along itstransverse axis 422. The upstanding sides 410 of the formed ice wells406 contain the water within the formed ice wells 406 as the ice formingplate 404 is rocked, allowing the water to run back and forth across thesurface of a clear ice piece (not shown in FIG. 35A) as it is formed,resulting in freezing of the clear ice piece from the bottom up. The iceforming plate 404 can then be inverted, and twisted to expel the clearice pieces.

In addition to the multiple configurations described above, as shown inFIGS. 36-37, the ice maker 52 according to the present invention mayalso have a controller 440 which receives feedback information 442 froma sensor 444 regarding the volume of usage of clear ice pieces 98 anduses the feedback 442 to determine an appropriate energy mode for theproduction of clear ice pieces 98, for example a high energy mode or alow energy mode. The controller 440 then sends a control signal 450,instructing a plurality of systems which aid in ice formation 452whether to operate in the high energy mode or the low energy mode.

The sensor 444 may detect, for example, the level of ice 98 in an icebin 64, the change in the level of ice 98 in the bin 64 over time, theamount of time that a dispenser 66 has been actuated by a user, and/orwhen the dispenser has been actuated to determine high and low ice usagetime periods. This information 442 is typically transmitted to thecontroller 440, which uses the information 442 to determine whether andwhen to operate the ice maker 52 in a high energy mode or a low energymode based upon usage parameters or timer periods of usage. This allowsthe ice maker 52 to dynamically adjust its output based on usagepatterns over time, and if certain data are collected, such as the timeof day when the most ice 98 is used, the ice maker 52 could operatepredictively, producing more ice 98 prior to the heavy usage period.Operating the ice maker 52 in a high energy mode would result in thefaster production of ice 98, but would generally be less efficient thanthe low energy mode. Operating in the high energy mode would typicallybe done during peak ice usage times, while low energy mode would be usedduring low usage time periods. An ice maker 52 having three or moreenergy modes of varying efficiencies may also be provided, with thecontroller 440 able to select an energy mode from among the three ormore energy modes.

One example of an ice maker 52 which could be operated by such acontroller 440 would be an ice maker 52 having a plurality of systems452 which operate to aid in the formation of clear ice pieces 98,including an oscillating system as described above, a thermoelectriccooling system as described above, a forced air system to circulate warmair as described above, a forced air system to circulate cold air asdescribed above, a forced air system to circulate warm air as describedabove, a housing 54 which is split into a first air chamber 254 and asecond air chamber 256 with a temperature gradient therebetween asdescribed above, and a thermoelectric heating system (to aid inharvesting clear ice pieces) as described above.

Operating an ice maker 52 in a high energy mode could include, forexample, the use of a particular oscillation setting, a thermoelectricdevice setting, one or more air circulator settings for use during theice freezing process, wherein the settings in the high energy moderequire more energy, and result in the faster formation of clear icepieces 98. The high energy mode could also include using thethermoelectric device 102 to provide a higher temperature to the iceforming plate 76 to cause a faster release of ice pieces 98 during theharvest process and to shorten cycle time for filling and making the icepieces.

The low energy mode could also include a delay in dispensing water intothe ice tray, or a delay in harvesting the clear ice pieces 98 from theice tray 70 as well as lower electronic power (energy) use by the motors112, 114 and thermoelectric devices 102 than the normal mode or highenergy mode. Such lower energy use may include no forced air, norequirement to drop the temperature of the second air chamber or iceforming plate, and harvesting can be done with minimal heating to theice forming plate over a longer period of time, if needed.

Additionally, in certain embodiments the controller 440 is able toindividually control the different systems, allowing at least one system452 to be directed to operate in a low energy mode while at least oneother system 452 is directed to operate in a high energy mode.

It will be understood by one having ordinary skill in the art thatconstruction of the described invention and other components is notlimited to any specific material. Other exemplary embodiments of theinvention disclosed herein may be formed from a wide variety ofmaterials, unless described otherwise herein. In this specification andthe amended claims, the singular forms “a,” “an,” and “the” includeplural reference unless the context clearly dictates otherwise.

Where a range of values is provided, it is understood that eachintervening value, to the tenth of the unit of the lower limit unlessthe context clearly dictates otherwise, between the upper and lowerlimit of that range, and any other stated or intervening value in thatstated range, is encompassed within the invention. The upper and lowerlimits of these smaller ranges may independently be included in thesmaller ranges, and are also encompassed within the invention, subjectto any specifically excluded limit in the stated range. Where the statedrange includes one or both of the limits, ranges excluding either orboth of those included limits are also included in the invention.

It is also important to note that the construction and arrangement ofthe elements of the invention as shown in the exemplary embodiments isillustrative only. Although only a few embodiments of the presentinnovations have been described in detail in this disclosure, thoseskilled in the art who review this disclosure will readily appreciatethat many modifications are possible (e.g., variations in sizes,dimensions, structures, shapes and proportions of the various elements,values of parameters, mounting arrangements, use of materials, colors,orientations, etc.) without materially departing from the novelteachings and advantages of the subject matter recited. For example,elements shown as integrally formed may be constructed of multiple partsor elements shown as multiple parts may be integrally formed, theoperation of the interfaces may be reversed or otherwise varied, thelength or width of the structures and/or members or connector or otherelements of the system may be varied, the nature or number of adjustmentpositions provided between the elements may be varied. It should benoted that the elements and/or assemblies of the system may beconstructed from any of a wide variety of materials that providesufficient strength or durability, in any of a wide variety of colors,textures, and combinations. Accordingly, all such modifications areintended to be included within the scope of the present innovations.Other substitutions, modifications, changes, and omissions may be madein the design, operating conditions, and arrangement of the desired andother exemplary embodiments without departing from the spirit of thepresent innovations.

It will be understood that any described processes or steps withindescribed processes may be combined with other disclosed processes orsteps to form structures within the scope of the present invention. Theexemplary structures and processes disclosed herein are for illustrativepurposes and are not to be construed as limiting.

It is also to be understood that variations and modifications can bemade on the aforementioned structures and methods without departing fromthe concepts of the present invention, and further it is to beunderstood that such concepts are intended to be covered by thefollowing claims unless these claims by their language expressly stateotherwise.

What is claimed is:
 1. An ice tray comprising: a twistable ice formingplate that is thermally conductive and comprises a top surface, anunderside and a plurality of ice forming ice wells therein wherein theplurality of ice wells have a bottom surface and at least one wallextending upwardly from the bottom surface and wherein each wall has aninterior ice well facing surface; and an insulating layer applied over aportion of the twistable ice forming plate and extending along a portionof the at least one wall of the plurality of ice wells and terminatingalong the surface of the at least one wall such that the bottom surfaceof the plurality of ice wells are free of insulating layer therebyforming a partially conductive and partially insulated ice tray.
 2. Theice tray of claim 1, wherein the insulating layer extends from the topsurface downwardly along the at least one wall of the ice wells andtapers until it terminates along the at least one wall.
 3. The ice trayof claim 2, wherein each ice well comprises at least two walls thatextend upwardly from the bottom surface.
 4. The ice tray of claim 1,wherein the bottom surface of the ice wells is flat.
 5. The ice tray ofclaim 1, wherein the twistable ice forming plate is a metallic materialand the insulating layer is a polymeric insulating material.
 6. The icetray of claim 1, wherein the ice tray further comprises an evaporatorelement thermally coupled to the underside of the twistable ice formingplate along an outside of the ice wells.
 7. The ice tray of claim 6,wherein the evaporator element extends along a transverse axis of thetwistable ice forming plate.
 8. The ice tray of claim 7, wherein theevaporator element further comprises a first coil proximate a first endof the twistable ice forming plate and a second coil proximate a secondend of the twistable ice forming plate.
 9. The ice tray of claim 6,wherein the evaporator element is configured and positioned to allow thetwistable ice forming plate to flex when a drive body reciprocallyrotates the twistable ice forming plate.
 10. The ice tray of claim 1,wherein a thermoelectric element is engaged with the underside of thetwistable ice forming plate and supplies cooling to the underside of thetwistable ice forming plate to form clear ice formed from the bottom ofthe ice wells upwardly within the ice wells.
 11. An ice try comprising apartially conductive and partially insulated ice forming plate rotatablycoupled with a housing and horizontally suspended within an interiorvolume of the housing and comprising ice wells where each ice well has abottom surface, and at least two sides that extend upwardly from thebottom surface and the partially conductive and partially insulated iceforming plate has an underside; wherein the ice forming plate is a heatconductive material and wherein each of the sides comprise an interior,ice forming cavity facing surface and the ice forming plate has a topsurface, which is generally at an uppermost portion of the ice wells;wherein the ice forming plate further comprises an upper portion that isproximate a top end of the sides and the interior, ice forming cavityfacing surface adjacent the top end; and an insulating layer appliedover the upper portion to form the partially conductive and partiallyinsulated ice tray where the conductive base layer is exposed proximatethe bottom surface and the insulating layer covers the upper portion.12. The ice tray of claim 11, wherein a cold source is thermally coupledto the bottom of the partially conductive and partially insulated icetray and configured to freeze water retained within the ice wells fromthe bottom surface upward and to produce clear ice pieces.
 13. The icetray of claim 11, wherein the ice forming plate is a metallic materialand the insulating layer is a polymeric material.
 14. The ice tray ofclaim 12, wherein the cold source comprises a thermoelectric devicehaving a first side engaged with the underside of the ice forming platewhere the underside is the side opposite a water receiving side of theice forming plate.
 15. The ice tray of claim 11, wherein the insulatinglayer is polypropylene that is molded onto the ice forming plate andwherein the ice forming plate is a metallic conductive base layer andwherein the insulating layer is mechanically engaged with the metallicconductive base layer and overlaid over the metallic conductive baselayer without attaching or secured in other removable or non-removableways.
 16. The ice tray of claim 11, wherein the ice forming plate is ametallic material and the insulating layer is a polymeric materialcovering the entire top surface and the upper portions of the ice wells.17. The ice tray of claim 12, wherein the cold source comprises anevaporator element thermally coupled to the underside of the ice formingplate where the underside is the side opposite a water receiving side ofthe ice forming plate.
 18. The ice tray of claim 17, wherein theevaporator element extends along a transverse axis of the ice formingplate and further comprises a first coil proximate a first end of theice forming plate and a second coil proximate a second end of the iceforming plate and with an interconnecting conduit therebetween.
 19. Aice forming and thermally conductive and thermally insulating clear iceforming tray that comprises a top surface, an underside and a pluralityof ice forming ice wells therein wherein the plurality of ice wells havea bottom surface and at least one wall extending upwardly from thebottom surface and wherein each wall has an interior ice well facingsurface; and an insulating layer applied over a portion of the clear iceforming tray and extending along a portion of the at least one wall ofthe plurality of ice wells and terminating along the surface of the atleast one wall such that the bottom surface of the plurality of icewells are free of insulating layer thereby forming a partiallyconductive and partially insulated ice tray.
 20. The ice forming andthermally conductive and thermally insulating clear ice forming tray ofclaim 19, wherein the insulating layer is a polymeric material and trayfurther comprises a cold source that comprises an evaporator elementthermally coupled to an underside of the partially conductive andpartially insulated ice tray where the underside is the side opposite awater receiving side of the partially conductive and partially insulatedice tray.